{"id":84076,"date":"2016-01-14T20:44:13","date_gmt":"2016-01-14T18:44:13","guid":{"rendered":"https:\/\/www.technion.ac.il\/blog\/cardiac-cells-trained-as-pacemakers\/"},"modified":"2016-01-14T20:44:13","modified_gmt":"2016-01-14T18:44:13","slug":"cardiac-cells-trained-as-pacemakers","status":"publish","type":"post","link":"https:\/\/www.technion.ac.il\/en\/blog\/cardiac-cells-trained-as-pacemakers\/","title":{"rendered":"Cardiac Cells Trained as Pacemakers"},"content":{"rendered":"

Mechanical Stimulation of Cardiac Cells Could Make Better Pacemakers<\/b><\/h2>\n

Discovered importance of mechanical communication could drive development of new therapies for cardiovascular diseases<\/b><\/h4>\n
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Schematic representation of the experimental setup: a mechanical device generates periodic mechanical deformations in the underlying substrate. The amplitude and direction of the mechanical deformations mimic those generated by a beating cardiac cell<\/figcaption><\/figure>\n

In a breakthrough that could change the future of pacemakers, Technion-Israel Institute of Technology researchers have used mechanical stimulation to \u201ctrain\u201d cardiac cells to beat at a given rate.<\/span><\/p>\n

The team\u2019s findings, published this week in <\/span>Nature Physics<\/i><\/strong><\/span><\/a>,<\/strong><\/span><\/a> also demonstrate for the first time that direct physical contact with the cardiac cells is not required to synchronize their beating. <\/span><\/p>\n

As long as the cardiac cells are in the tissue being mechanically stimulated, they are trained by the stimulation, with long-lasting effects that persist even after it is stopped.<\/span><\/p>\n

\u201cCell-cell communication is essential for growth, development and function,\u201d explains, Assistant Professor Shelly Tzlil, of the Technion Faculty of Mechanical Engineering. <\/span><\/p>\n

\u201cWe have shown that cells are able to communicate with each other mechanically by responding to deformations created by their neighbors. The range of mechanical communication is greater than that of electrical and chemical interactions. Another significant discovery is that the duration of cell pacing is greater when the stimulus is mechanical, indicating that mechanical communication induces long-term alterations <\/span><\/p>\n

The stimulation was applied by an artificial \u201cmechanical cell,\u201d consisting of a tiny probe (with a 0.0025 cm tip diameter) that generated (via cyclical indenting and pulling) periodic deformations in the underlying substrate (cardiac tissue). The deformations mimicked those generated by a beating cardiac cell that was also in the tissue. After a brief 10-minute training period, the cardiac cell synchronized its beating rate with the mechanical cell. Furthermore, the cardiac cell maintained the induced beating rate for more than one hour after mechanical stimulation was stopped.<\/span><\/p>\n

\u201cIn this study, we show that an isolated cardiac cell can be trained to beat at a given frequency by mechanically stimulating the underlying substrate,\u201d says Tzlil. \u201cMechanical communication plays an important role in cardiac physiology, and is essential for converting electrical pacing into synchronized beating. Impaired mechanical communication will lead to arrhythmias even when electrical conduction is working properly. \u00a0The medical implication is that adding mechanical elements to electrical pacemakers will significantly improve their efficiency.\u201d<\/span><\/p>\n

The Full Article<\/a><\/strong><\/span><\/p>\n

Synchronized beating of mechanically-coupled cardiac cells: time-lapse imaging of a pair of beating cardiac cells on a 3.8kPa substrate. Phase contrast (left) and calcium imaging (right). The scale bar is 20 microns. <\/em><\/strong><\/p>\n


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